Physical and Biological Characteristics of the Antitumor Drug Actinomycin D Analogues Derivatized at N-Methyl-l-valine Residues

Abstract

The crystal structure of the DNA-actinomycin D (AMD) complex and a simple molecular modeling study indicated that AMD analogues derivatized at N-methyl-L-valine residues (fifth amino acid residue in the cyclic depsipeptide of AMD) could bind to DNA as strongly as the parent AMD. The analogues in which N-methyl-L-valine residues were replaced with L- and D-forms of N-methylvalines, N-methylthreonines, N-methylphenylalanies, N-methyltyrosines, and N-methyl-O-methyltyrosines have been totally synthesized. The characteristics of binding of the analogues to various DNAs including DNA-1 [d(TATATATGCATATATA)], DNA-2 [d(TATATACGCGTATATA)], DNA-3 [d(ATATATAGCTATATAT)], and DNA-4 [d(ATATATGGCCATATAT)] have been examined by using visible absorption spectrum methods. The association constants calculated from the absorption spectra indicate that the modifications of the N-methyl-L-valine residues in the AMD molecule do affect the DNA binding characteristics of the analogues. The L-aromatic analogues bind slightly better than the L-aliphatic analogues except for binding to DNA-1 (-TGCA-), whereas the D-aliphatic analogues bind consistently better than the D-aromatic analogues. In the L-form analogues, the L-Tyr analogue has the highest overall association constant, whereas the D-Val analogue has the highest association constant among the D-form analogues. In spite of substitution of bulky aromatic groups, the D-aromatic analogues bind to the DNA-1 quite well. However, D-aromatic analogues have significantly reduced their binding capacities to the other DNAs, indicating that the substitution of the D-aromatic residues creates a unique four-base sequence preference (-TGCA-). The RNA polymerase inhibitory activities of the AMD analogues in vivo have been examined using human cells (HeLa). All AMD analogues except for the L-Thr analogues severely inhibit RNA synthesis at relatively low drug concentrations. The D-Val, L-OMT, L-Phe, and D-Phe analogues inhibit RNA synthesis more strongly than the natural antibiotic (AMD itself).